High-rate proximity detection with the ability to provide notification

ABSTRACT

Techniques are presented for identifying mobile devices within a coverage legion of a wireless station Positions for mobile devices, if any, within the coverage region are determined. It is then determined whether the positions are within one or more defined areas, called “notification areas” herein. Additionally, selected mobile devices within notification areas are sent messages. The selected mobile devices ale selected via certain criteria, including, for instance, campaign specifications and subscriber information A message can be sent to a mobile device if the subscriber corresponding to the mobile device has indicated an acceptance of a category of notifications for the message and for the publisher who is publishing the notifications. The category could be traffic conditions and the publisher could be a Department of transportation having responsibility for a particular freeway. These are two examples of multiple criteria for selecting mobile devices to which messages could be sent.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.11/526,443 which is a continuation of U.S. patent application Ser. No.10/315,651, filed on Dec. 10, 2002, each incorporated by referenceherein.

FIELD OF THE INVENTION

The present invention relates to wireless communication systems and,more particularly, relates to messaging over wireless networks.

BACKGROUND OF THE INVENTION

Increasingly, mobile devices, such as cellular telephones, can transmitor receive text messages For example, the short message service (SMS) isavailable for cellular phones, facsimile machines and Internet protocol(IP) addresses. The SMS protocol allows small text messages, with a sizeless than 160 alphanumeric characters, to be communicated to or from amobile device. Similarly, the wireless application protocol (WAP) is aspecification allowing mobile devices to communicate multimedia messageswith one another

Messaging capability extends the functionality of mobile devices andallows mobile users to send additional information to each other.Commercial vendors have also begun to discover that sending messages tomobile devices is beneficial. For example, systems exist whet e acommercial vendor can send a message to mobile devices proximate thevendor. Nonetheless, there are problems with the current schemes forsending proximity-based messages to mobile devices, and improvedtechniques are needed that allow messages to be sent to proximate mobiledevices.

SUMMARY OF THE INVENTION

Aspects of the present invention provide high-rate proximity detectionfor mobile devices, and can provide notification to mobile devicesdetermined to be proximate a wireless station.

In one aspect of the invention, techniques are presented for identifyingmobile devices that ate within a coverage region of a wireless station.Positions for mobile devices, if any, within the coverage region aredetermined. It is then determined whether the positions are within oneor more defined areas, called “notification areas” herein.

In another aspect of the invention, selected mobile devices withinnotification areas are sent messages The selected mobile devices areselected via certain criteria, including, for instance, campaignspecifications and subscriber information As an example, a message canbe sent to a mobile device if the subscriber corresponding to the mobiledevice has indicated an acceptance of a category of notifications forthe message and for the publisher who is publishing the notifications.The category could be, for example, traffic conditions and the publishercould be, for instance, a Department of Transportation havingresponsibility for a particular freeway. These are two examples ofmultiple criteria for selecting mobile devices to which messages couldbe sent

A more complete understanding of the present invention, as well asfurther features and advantages of the present invention, will beobtained by reference to the following detailed description anddrawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a flowchart of a method for proximity detection and fornotification of proximate mobile devices, in accordance with oneembodiment of the present invention;

FIG. 2 is a block diagram of a high-rate proximity detection subsysteminteracting with a mobile device, in accordance with one embodiment ofthe present invention;

FIG. 3 is a block diagram of a notification system interacting with acarrier gateway and a mobile device, in accordance with one embodimentof the present invention;

FIG. 4 is an example of a proximity detection system database, inaccordance with one embodiment of the present invention;

FIGS. 5A and 5B are examples of a campaign specification database, inaccordance with one embodiment of the present invention;

FIG. 6 is an example of a subscriber information database, in accordancewith one embodiment of the present invention; and

FIG. 7 is block diagram of an exemplary computer system suitable forimplementing aspects of the present invention, in accordance with oneembodiment of the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

The present invention, among other things, satisfies a desired abilityto send a text or multimedia message to wireless devices when thewireless devices are determined to be in particular notification areas.There are a number of exemplary scenarios for which the presentinvention can provide notification: (1) a consumer can be sent a couponfor a new store in a shopping mall when the consumer enters the parkinglot for the mall; (2) a consumer can be notified, as the consumer entersa shopping center, that an office supply store has a back-to-school salethat ends in about two hours; (3) tourists can be sent brief multimediadescriptions of the monuments in the Washington, D.C. mall as they entereach area that surrounds a monument; (4) fair-goers can be sentcommunications of the current events inside the venue they areapproaching; (5) drivers who enter a certain section of highway can benotified that construction two miles ahead is causing a backup and theyshould take a detour; (6) drivers can be notified that, because ofsevere fog conditions ahead, they should reduce speed immediately; and(7) a message can be sent to all subscribers in a certain area thattheir water supply will be cut off in half an hour to replace a sectionof pipe.

To support these applications, a notification system could offer certaincapabilities Some exemplary capabilities ate described below, but itshould be noted that the present invention is not limited to thesecapabilities, nor does the present invention need provide all of thesecapabilities. One such capability, for instance, is precisely definedand arbitrarily located notification areas. In the scenario (1) above,the notification area is defined to be the parking lot of a shoppingmall, so that commuters on a nearby highway do not receive the coupon.The shopping mall is a precisely defined notification area. In theWashington tour guide case, scenario (3) above, the areas could be suchthat tourists approaching the Lincoln Memorial do not receive thedescription of the Washington Monument. Another desirable capability isthe ability to detect entrance to a notification area within a shorttime period, such as one minute. This is beneficial in order to supportnotifications for drivers Yet another desirable capability is theability to use wireless handsets with automatic position identificationcapability that will be deployed for Enhanced 911 emergency positionservice.

There are conventional systems designed for providing thesecapabilities, but these conventional systems employ an architecture thatis not scalable. These conventional systems are formed on agateway-based architecture for position determination, in which thecarrier network provides a server for handling all position requests.Given a terminal identifier (e g., a subscriber phone number), theserver will first determine which mobile switching center (MSC) isserving the user. It will then forward the request to theposition-determining technology deployed by that MSC The global systemfor mobile communication (GSM) Position Services architecture is anexample of such a conventional architecture See, for instance, theEuropean Telecommunication Standardization Institute (ETSI) technicalstandard (IS) 101 724 or GSM 3 71, the disclosures of which are herebyincorporated by reference

The architecture in the cited standards serves common applications thatrequire the occasional position of an individual subscribers or even thetracking of a small number of subscribers. But because of the gatewayarchitecture, conventional systems using these types of architecturescannot scale to handle a large number of requests, such as thousands orhundreds of thousands of requests per second Because each request forposition has to go through one server, and from that server to localposition-determining technologies and then back to the server, it willbe very difficult for the server to handle thousands or hundreds ofthousands of requests in order to track mobile devices Some cellularservice providers, for example, have millions of subscribers, andtracking all of these subscribers will be problematic using conventionalarchitectures.

The present invention provides methods and apparatus that scale to allowhigh-rate proximity detection and notification for very large numbers ofsubscribers.

Certain embodiments of the present invention impose no additionalrequirements beyond E911 with respect to handsets The latter requirementis important to carriers because certain embodiments make use oftechnology which is currently being deployed In addition to the abovecapabilities, embodiments of the present invention can address twofunctional capabilities related to supporting a wide range ofapplications: a system should support a variety of notification forms,including SMS messages, WAP Push services, and application-specificforms; and notification publishers (e.g., retailers) should have theability to personalize the notification

Referring now to FIG. 1, a method 100 is shown for proximity detectionand for notification of proximate mobile devices. Method 100 isexemplary and the method 100 provides an overview of the presentinvention, but additional detail is presented below. Aspects of thepresent invention take advantage of the natural geographic distributioninherent in wireless networks, and push position queries into thewireless network, close to the positioning technology. This contrastswith the approach of having one central position server that is providedby the wireless carrier to serve less demanding applications.

Method 100 begins in step 110 when mobile devices within a coverageregion are determined. It is possible to determine which devices arewithin a coverage region of a wireless station. For instance, incellular networks, a base station subsystem can determine which cellularphones are within the coverage region for the base station subsystemSimilarly, an access point can determine which mobile devices are in thecoverage region for the access point. A coverage region is an area inwhich a mobile device and a wireless station can communicate.

In step 120, the positions of the mobile devices within a coverageregion are determined. Generally, there is a particular proximitydetection technology that services a particular coverage region orperhaps a few coverage regions. By determining the positions of mobiledevices within a coverage region with proximity detection technology,the tracking of mobile devices is moved closer to the devices Thisreduces the bottlenecks that can occur by having a single serverattempting to ascertain positions of mobile devices. Such positiondetection technology could employ, for example, triangulation or globalpositioning system (GPS) techniques. Any technology suitable fordetermining a position of a mobile device may be used.

In step 130, it is determined whether any mobile devices are withinnotification areas. A notification area is an area defined by apublisher. A notification area can be any arbitrary shape. Notificationareas are described in more detail below. Publishers are those entities,such as commercial vendors, who define the notification areas and whoalso define messages to be sent to those mobile devices in thenotification areas. Positions of mobile devices are used to determinewhether any mobile devices are within a notification areas.

In step 140, messages are sent to selected mobile devices that are innotification areas. Mobile devices can be selected based on a number ofcriteria. For example, all mobile devices in a notification area can beselected, regardless of any preferences by publishers or subscribers. Asdescribed in more detail below, though, generally some preferences willbe used to select mobile devices. As an example, publishers can setdifferent categories, among other criteria. Subscribers who are usingmobile devices can opt out or opt into these categories. In the presentdisclosure, a “subscriber” and a “mobile device” will both be treated ashaving positions, although it is possible for one subscriber to havemultiple mobile devices In the latter instance, a mobile device beingtracked will still have a subscriber and there will generally besubscriber preferences associated with the mobile device. A publishermay desire to send an advertisement to mobile devices in a particularnotification area, but a subscriber using a mobile device may opt out ofcommercial advertisement and, consequently, will not receive theadvertisement. Another subscriber, using a different mobile device,might opt into or have no preference regarding commercialadvertisements. Thus, this other subscriber will receive theadvertisement.

Therefore, method 100 allows notifications to be sent to mobile devicesproximate a wireless station. Moreover, method 100 allows high-rateproximity detection, as proximity detection and determination of whethermobiles are in notification areas is spread out instead of beingcentralized.

Referring now to FIG. 2, a high-rate proximity detection subsystem 200is shown interacting with a mobile device 260. High-rate proximitydetection subsystem 200 performs, in this example, steps 110, 120, and130 of method 100 of FIG. 1. High-rate proximity detection subsystem 200comprises local proximity detection systems 230-1 through 230-N(collectively, local proximity detection systems 230), a mobileswitching center/visitor position register (MSC/VLR) 210, a querydistributor 220, and a subscriber database 225. Each local proximitydetection system 230 comprises a base station subsystem 235, a proximitydetection technology 240, a proximity detection module 245, anotification areas database 250, and a subscriber positions database255. The subscriber database 225 comprises two subscriber subsets 226and 227 that comprise a subscriber set 228. It should be noted thatterminology has been borrowed from the GSM wireless architecture, but itshould be understood that the present invention applies to all wirelessnetworks where a position of a wireless device can be determined

The number of local proximity detection systems 230 per querydistributor 220 and MSC/VLR 210 is usually small, such as several localproximity detection systems 230 per query distributor 220 and MSC/VLR210.

Each base station subsystem 235, as is known in the art, generallyincludes a base station controller (not shown) and one or mole basetransceiver stations (not shown) The area in which a base transceiverstation and a mobile device are able to receive signals from each otherdefines a “cell” in cellular phone terminology. In this example, thebase station subsystem 235 is a wireless station and the cell is acoverage region for the wireless station. In the example of FIG. 2,mobile device 260 can communicate with base station subsystem 235-N butcannot communicate with base station subsystem 235-1. Mobile device 260is therefore within the coverage legion of local proximity detectionsystem 230-N but not within the coverage region of local proximitydetection system 230-1

Proximity detection technology 240 is whatever technology is used forproximity detection. This could be timing, triangulation, GPSinformation, or any other technology for determining position of amobile device 260. It should also be noted that a simple proximitydetection technology 240 such as determining whether a mobile device 260is within a cell may be suitable for some applications. The presentinvention will beneficially operate regardless of the type of proximitydetection technology 240 used.

Each proximity detection module 245 communicates with the positiondetection technology 240 and the query distributor 220 If there aremultiple proximity detection modules 245 deployed for a position areaserved by the MSC/VLR 210, then a query distributor 220 will servemultiple proximity detection modules 245. In this context, a positionarea of MSC/VLR 210 comprises the set of coverage areas defined by thebase station subsystems 235.

The query distributor 220 has, in certain embodiments, theresponsibility of periodically directing a proximity detection module245 to obtain the positions of a set of currently served subscribers.The query distributor 220 may obtain this set from the MSC/VLR 210 or itmay obtain the set from the base station subsystem 235. The querydistributor 220 may also maintain a subscriber database 225, if desired,that contains the set 228 of currently served subscribers. In the caseof multiple proximity detection modules 245 serving a position area ofthe MSC/VLR 210, subscriber identifiers obtained from the MSC/VLR 210will be accompanied by the base station subsystem 235 serving eachsubscriber. The query distributor 220 maintains an association of basestation subsystem 235 to proximity detection module 245, allowing thequery distributor 220 to split the set of subscriber identifiers intosubsets 226, 227, each subset 226, 227 containing only those subscribersserved by the base station subsystem 235 to which the proximitydetection module 245 is associated via the proximity detectiontechnology 240.

For the example of FIG. 2, a set 228 of currently served subscribers isdivided into two subsets 226, 227 of currently served subscribers Thequery distributor 220 has, in this example, stored these subsets 226,227 in subscriber database 225, although subscriber database 225 is notrequired. For local proximity detection system 230-N, the subset 226could be the subscriber identifier “subID260” for “SUB ID” portion ofthe subset 226 for the mobile device 160. Subset 226 also comprisesanother identifier (such as “PDM245-N”), shown as “PDM” in FIG. 2, tocorrelate the subscriber identifier of “subID260” with the localproximity detection system 230-N The subset 227 of currently servedsubscribers for the local proximity detection system 230-1 is a nullset, as thee are no currently served subscribers within the coveragelegion of the local proximity detection system 230-1. Thus, subset 227would be a null subscriber identifier and another identifier (such as“PDM245-1”) to correlate the null subscriber identifier with the localproximity detection system 230-1.

A query distributor 220 may, alternatively, maintain a database (notshown) that associates a base station subsystem 235 with the localproximity detection system 230 serving the base station subsystem 235When a subscriber identifier obtained from the MSC/VLR is accompanied bythe serving base station subsystem 235, this database facilitates thedistribution of positioning queries to the local proximity detectionsystems 230.

A proximity detection module 245 may be associated with multipleproximity detection technologies 240, for flexibility in deployment.Also, a query distributor 220 may obtain its set 228 of currently-servedsubscribers directly from the base station subsystem 235. Furthermore,the query distributor 220 may obtain the set 228 of subscribers invarious ways. For example, query distributor 220 may obtain the set 228of subscribers by periodic direct request, or it may receive them viaupdate events from the base station subsystem 235 or query distributor220 The precise nature of the interface depends on the networkinterfaces exposed by a particular carrier implementing the base stationsubsystem 235 and MSC/VLR 210.

Each, in certain embodiments, proximity detection module 245 maintains anotification areas database 250, which contains the mobile devices thatlie within the coverage region served by the proximity detection module245 Each record in the database comprises the geometry (e.g., ingeographical coordinates) of a notification area and a uniqueidentification of that notification area. This is described in moredetail below. Additional information may include a start time indicatingwhen a notification area becomes active, and a stop time indicating whenthe notification area becomes inactive The proximity detection module245 may use this information to locally manage the lifetime ofnotification areas.

Given a set 228 of subscribers, a proximity detection module 245 willperiodically direct a corresponding proximity detection technology 240to compute positions of subscribers in a corresponding subset 226, 227and therefore positions of mobile devices corresponding to thesubscribers The direction may occur through a normal interface (notshown) from the proximity detection technology 240 for positionrequests, or the proximity detection technology 240 may offer a separateinterface (not shown) for tracking requests. For each subscriberposition, stored in subscriber positions database 255, received from theproximity detection technology 240, the proximity detection module 245will query a corresponding notification areas database 250 to determinewhich, if any, notification areas the subscriber lies within. For eachnotification area the subscriber lies within, the proximity detectionmodule 245 sends a “proximity” message to another module, which isdiscussed below

The proximity detection module 245 is, in one embodiment, responsiblefor determining that the proximity detection module 245 has alreadydetected the entrance of a particular subscriber to a particularnotification area and, therefore, not sending duplicate “proximity”messages The proximity detection module 245, in certain embodiments, isalso responsible for detecting when a subscriber has exited an area.

Since the proximity detection technology 240 will generally continue tohandle conventional position requests forwarded by the MSC/VLR 210, theproximity detection module 245 may, as an additional function to makehandling of the conventional position requests more efficient, maintaina subscriber positions database 255 storing the last subscriber positioncomputed. The proximity detection technology 240 will then simplyforward position requests to the proximity detection module 245. Or, theproximity detection module 245 may present a proximity detectiontechnology 240 interface (not shown) to the MSC/VLR 210.

Turning now to FIG. 3, a notification system 300 is shown Notificationsystem 300 interacts with a carrier gateway 380, which interacts with amobile device 260. The notification system 300 comprises the high-rateproximity detection subsystem 200 as described in FIG. 2 and centralnotification subsystem 310. The central notification subsystem 310comprises a notification publisher interface 315, a specification module320, PDS information database 330, a campaign specifications database340, a subscriber preferences database 350, a notification module 360,and a message personalization module 370 In this example, centralnotification system 310 performs step 140 of FIG. 1, which is sendingmessages to selected mobile devices that are in a notification area

Publisher of notification areas create campaign specifications and enterthese campaign specifications via the notification publisher interface315. Notification publisher interface 315 may be implemented, forinstance, as a Web page or an applet. The campaign specifications atereceived by the specification module 320, which stores them in acampaign specifications database 340 Campaign specifications database340 is described in more detail in reference to FIGS. 5A and 5B Eachcampaign specification, as described in more detail below, comprises inthis example the following: (a) a publisher identification (ID); (b) acampaign ID; (c) one or more notification areas for the campaign; (d) amessage of some form to be delivered to a subscriber; (e) an indicationof the type of the method (e.g., SMS ox WAP Push) used to transmit themessage; (f) a start time indicating when the campaign is to begin; (g)a stop time indicating when the campaign should end; (h) informationindicating the category of campaign, such as whether its purpose iscommercial and promotional, commercial and informational (e.g, tourism),entertainment, traffic, or emergency or any combination thereof, and (i)specification of a message-customization mechanism, to be describedbelow. It should be noted that these are only examples and a campaignspecification may contain different, more, or less information than whathas been and will be described

For each campaign specification received, the specification module 320determines the affected high-rate proximity detection subsystems 200 bycomparing the notification areas in the specification (e g, stored incampaign specifications database 340) to the coverage regions of thehigh-rate proximity detection subsystems 200, recorded in PDSinformation database 330. An example PDS information database 330 isshown in FIG. 4. For each high-rate proximity detection subsystem 200whose coverage region intersects the notification areas in thespecification, the specification module 320 sends the notification areadatabase 250 updates for that high-rate proximity detection subsystem200 These updates comprises for example, sending notification areaupdates 321 to the high-rate proximity detection subsystem 200. Thenotification area updates 321 generally comprise notification areas andtheir associated notification area IDs, start times, and end times, asdescribed in more detail in reference to FIG. 5.

Proximity events 361 sent from the high-rate proximity detectionsubsystem 200 to the notification module 360, in certain embodiments,comprise a subscriber ID (not shown) and notification area ID (notshown). Any events suitable to alert a system that a mobile device iswithin (or perhaps has left) a proximity of wireless station aresuitable. The notification module 360 looks up an associated campaignspecification in the campaign specifications database 340 using thenotification area ID and composes a notification according to theinformation in the returned campaign specification. Notification module360 then, optionally, applies subscriber preferences stored insubscriber preferences database 350 to determine if the subscriberwishes to receive this notification. For each subscriber known to thesystem, the subscriber preferences database 350 records, as shown inmore detail in FIG. 6, the following: (a) what categories ofnotifications the subscriber is interested in (e.g., using the same setof categories used by publishers); (b) what publishers the subscriberdoes not want to receive notifications from; (c) what exceptions, ifany, to (b) the subscribes has registered, and (d) what specificcampaigns the subscriber has registered for. The preceding were onlyexamples, and a subscriber preferences database 350 may have different,more, or less information than that described.

Thus, a proximity event 361 such as “<subID, areaID>” could be known bythe notification module 360 The notification module 360 may alsodetermine the campaign ID (e.g., “campID”), the publisher ID (e g.,“pubID”), and the category associated with the areaID. The notificationmodule 360 also optionally determines, for a subscriber; the acceptedcategories (e.g “acceptedCategories”), blocked publishers (e.g,“blockedPublishers”), the accepted publishers (e.g.,“acceptedPublishers”), and accepted campaigns (e.g.,“acceptedCampaigns”) The notification module 360 then proceeds withnotification, for example, depending on the following: (campaigncategory IN acceptedCategories) AND (campaign.publisherID NOT INblockedPublishers) OR (campaign.publisherID IN acceptedpublishers) OR(campaign.campaignID IN acceptedCampaigns). It should be noted that thisformulation is only exemplary and other formulations may be used.

If the publisher has registered a message-personalization directive, thenotification module 360 will perform the directive. The directive mayconsist of a uniform resource locator (URL) for an external host (notshown) that will provide a message personalized for the particularsubscriber, or the publisher may have supplied a Java class, in thisexample the message personalization module 370, that will generate apersonalized message. The personalization message may be delivered backto notification module 360 in older for the notification module 360 totransmit the message to the carrier gateway 380. The notification module360 will then communicate with the carrier gateway 380 in order todeliver the notification. Alternatively, the personalization message maybe delivered directly to the carrier gateway 380. The method ofcommunication with the carrier gateway 380 generally depends on themessage type.

Notification processors 360 may be replicated for load balancing, usingwell-known techniques employed in highly loaded web sites.

It should be noted that FIGS. 2 and 3 are exemplary. Entities in thesefigures may be combined, subdivided, rearranged, or deleted. Forinstance, the specification module 320 may be combined with thenotification module 360. As another example, the specification module320 may be further subdivided into a module operating on campaignspecifications database 340 and subscriber preferences database 350 whendetermining whether to notify a mobile device 260, and another moduleoperating on PDS information database 330 and campaign specificationsdatabase 340 in order to determine whether notification area updates 321should be sent. As another example, the service adapter 220 could bebuilt into each proximity detection module 245.

Referring now to FIG. 4, an example of a PDS information database 330 isshown In this example, there are two high-rate proximity detectionsubsystems 200, which are “PDS 1” and “PDS 2.” The coverage region foreach high-rate proximity detection subsystem 200 is described via aseries of coordinates. Any technique for describing an area may be usedThe network address of each high-rate proximity detection subsystem 200is also given. The network addresses may also be stored as hyper texttransfer protocol (HTTP) addresses or other suitable addresses, ifdesired As described above, the PDS information database 330 is used todetermine to which high-rate proximity detection subsystems 200notification area updates 321 should be sent.

Referring now to FIGS. 5A and 5B, these figures show an exemplarycampaign specifications database 340 As can be seen in FIGS. 5A and 5B,the publisher Mall A has a new store campaign. The mall has an areabetween a number of coordinates 1 through P The message is “Mall A isproud to announce the grand opening of Store K, offering 15% off.” Inthis example, the Store K is offering 15 percent off but Mall A has notoffered a coupon directly to subscribers. This message is to bedelivered via a WAP push, and it is valid between December 10 at 11 a.m.to December 24 at 9 pm. The category is commercial and the messagecustomization is “message with map,” which means that a message willcontain a map showing the location of the new store, if the mobiledevice 260 supports this.

It should be noted that FIGS. 5A and 5B are merely exemplary. Othercriteria may be added, and criteria shown in campaign specificationsdatabase 340 can be removed For instance, a cellular phone system maychoose to make categories optional. Additionally, there may be multipleentries pet publisher For example, the publisher DOT already has twoseparate entries shown. In situations where more than one message methodand method customization might be performed for a single message, thiscan be indicated via two entries or a single entry. For instance, Mall Amight want to send its message via both SMS and WAP. In this case, the“WAP” message method could be changed to “SMS, WAP” and the “MESSAGEWITH MAP” message customization could be changed to “NONE, MESSAGE WITHMAP” so that SMS uses no message customization but WAP uses “MESSAGEWITH MAP”

Referring now to FIG. 6, an exemplary subscriber preferences database350 is shown. In this example, subscriber preferences database 350 hastwo subscribers, subscribers A and B Subscriber A has accepted allcategories, blocked no publishers and accepted all publishers, and hasaccepted the “COUPONS” campaign from Publisher A Publisher A publishes anumber of different coupons using the “COUPONS” campaign, and SubscriberA has accepted this campaign On the other hand, Subscriber B hasspecifically opted out of commercial categories and specificallydislikes Publisher A. However, Subscriber B has opted to receiveinformation from publisher DOT and Mall A Thus, even though Subscriber Bwill not, in general, receive commercial messages, Subscriber B will,under the exemplary formulation given above, receive commercial messagesfrom Mall A.

Turning now to FIG. 7, a computer system 700 is shown interacting with anetwork 770 and a medium 760. Computer system 700 may be used toimplement the method steps and apparatus described herein. For instance,computer system 700 may implement the frictions of specification module320 and the notification module 360. Computer system 700 comprises aprocessor 710, a memory 720, a network interface 730, and a mediainterface 740.

Processor 710 can be configured to implement the method steps andfunctions disclosed herein. The memory 720 could be distributed or localand the processor 710 could be distributed or singular. The memory 720could be implemented as an electrical, magnetic or optical memory, orany combination of these or other types of storage devices Moreover, theterm “memory” should be construed broadly enough to encompass anyinformation able to be read from or written to an address in theaddressable space accessed by processor 710. With this definition,information on network 770 is still within memory 720 because theprocessor 710 can retrieve the information from the network It should benoted that each distributed processor that makes up processor 710generally contains its own addressable memory space. It should also benoted that some or all of computer system 700 can be incorporated intoan application-specific or general-use integrated circuit.

As is known in the art, the methods and apparatus discussed herein maybe distributed as an article of manufacture that itself comprises amachine readable medium, such as medium 760, containing one or moreprograms which when executed implement embodiments of the presentinvention For instance, the machine readable medium may contain aprogram configured to determine whether the position of a mobile device260 is within a notification area. The machine readable medium may be arecordable medium (e g., a hard drive or an optical disk) or may be atransmission medium (e.g., a network 770 comprising fiber-optics, theInternet, or a wireless network using time-division multiple access,code-division multiple access, or other radio-frequency channel) Anymedium that can store information suitable for use with a computersystem may be used

It is to be understood that the embodiments and variations shown anddescribed herein are merely illustrative of the principles of thisinvention and that various modifications may be implemented by thoseskilled in the art without departing from the scope and spirit of theinvention.

1. A method for determining a position of one or more mobile devices,the method comprising the steps of: identifying mobile devices within acoverage region of a wireless station, wherein one of a plurality ofcoverage region processors is assigned to the coverage region;determining a position for at least one of the mobile devices identifiedto be within the coverage region of the wireless station; and reportingsaid position, wherein said report is generated by said assignedcoverage region processor.
 2. The method of claim 1, wherein saiddetermining step is performed periodically.
 3. The method of claim 1,wherein said report is generated in response to a query.
 4. An articleof manufacture for determining a position of one or more mobile devices,comprising: a computer readable medium containing one or more programswhich when executed implement the steps of; identifying mobile deviceswithin a coverage region of a wireless station, wherein one of aplurality of coverage region processors is assigned to the coverageregion; determining a position for at least one of the mobile devicesidentified to be within the coverage region of the wireless station; andreporting said position, wherein said report is generated by saidassigned coverage region processor
 5. The article of manufacture ofclaim 4, wherein said determining step is performed periodically.
 6. Thearticle of manufacture of claim 4, wherein said report is generated inresponse to a query
 7. An apparatus for determining a position of one ormore mobile devices, comprising: a memory; and at least one processor,coupled to the memory, operative to: identify mobile devices within acoverage region of a wireless station, wherein one of a plurality ofcoverage region processors is assigned to the coverage region; determinea position for at least one of the mobile devices identified to bewithin the coverage legion of the wireless station; and report saidposition, wherein said report is generated by said assigned coverageregion processor.
 8. The apparatus of claim 7, wherein said determiningstep is performed periodically
 9. The apparatus of claim 7, wherein saidreport is generated in response to a query.